Variable gain amplifier



Oct. 29, 1968 w. W. LANCASTER 3,408,587

VARIABLE GAIN AMPLIFIER Filed Aug. l5. 1966 AGC United States Patent O 3,408,587 VARIABLE GAIN AMPLIFIER William W. Lancaster, Philadelphia, Pa., Philco-Ford Corporation, Philadelphia, poration of Delaware Filed Aug. 15,1966, Ser. No.

11 Claims. (Cl.

assignor to Pa., a corsignals createa high AGC current and hence a high emitter current which forward biases the diode, provides a high of AGC supply AGC sensitivity for reduction of loading stage.

This invention relates to amplifiers and more particularly to a controllable gain amplifier having a particular gain control characteristic which makes the amplifier well suited for use as a radio frequency (RF) amplifier in a radio or TV receiver.

It is desirable `and common to include an RF amplifying stage in radio and television receivers in order to provide increased sensitivity for better reception of weak signals. The gain (amount of amplification) of the often the gain of one or more additional stages may be automatically by an AGC (automatic gain conat very low input signal levels, ratio is lower.

Another desideratum of an RF amplifier stage is low harmonic and intermodulation distortion. This can be RF stage and 3,408,587 Patented Oct. 29, 1968 effected if thel RF amplifier does sharply in any operating clipping occurred when changed by the AGC voltage of strong incoming signals drove the transistor into its cutoff region.

Accordingly, it is one object of the present invention toprovide a gain controllable amplllier which has high Another object of the present invention is to provide a gain controllable RF amplifier with reduced harmonic and cross modulation distortion.

Summary is reduced by supplying the AGC voltage to the the transistor in a bias of the transistor when stronger signals are input of forward received.

Drawing FIG. l is a schematic gain amplifier according diagram which shows a variable to the invention.

FIG. 2 in a graph which shows the gain of the amplifier Iof FIG. 1 as a function of AGC voltage or incoming signal strength. .Y

Description of circuit a controllable gain amplifier having gain characteristic is desired.

The stage includes an NPN transistor 16 improves AGC sensitivity by reducing the collector voltage of transistor 10 when more collector current is drawn. All of the components shown in the drawing, except resistor 16 and source 12, are desirably installed in a metal chassis. A capacitor 18, which may be a feedthrough capacitor which 1s installed at the point where the The incoming RF signal is coupled to the base of tranvoltage is also coupled of a resistor 22, which has a substantially higher value than the base-emitter circuit impedance of transistor in order to prevent the AGC circuit from loading the input signal. A second capacitor 24, which again may be a feedthrough capacitor, is provided around the AGC lead 26 to decouple the RF amplifier from the AGC circuit.

The AGC voltage, which is supplied to lead 26 from a subsequent stage (not shown), is a positive voltage whose value is proportional to the strength of the output signal at the secondary of transformer 14. In a television receiver, the AGC voltage may be derived from the synchronizing pulses by gating and filtering the output of a direct-coupled video amplifier in conventional fashion. Since a positivegoing AGC voltage is supplied to the base of an NPN transistor 10, the forward bias of transistor 10 will be increased in proportion to the strength of the output signal at the secondary winding of transformer 14.

The emitter of transistor 10 is connected to ground (the negative terminal of source 12) by means of serially connected resistors 28 and 30. Resistor 30 is shunted by a diode 32 and resistors 28 and 30 are bypassed by a capacitor 34. Diode 32, which may be a silicon diode having a forward offset voltage of about 0.6 volt, is poled so that it will conduct current from source 12 in the forward direction. In lieu of diode 32 any device may be used which undergoes a substantial change in impedance when a predetermined voltage is applied thereacross so as to produce a substantial change in the combined impedance of the device and resistor 30. In the case of the silicon diode, the impedance of device 32 changes from a value much higher than the impedance of resistor 30 to a value much lower than the impedance of resistor 30. Capacitor 34 provides a substantially infinite impedance to direct current and a substantially complete bypass to signal frequencies and hence prevents signal degeneration in the emitter circuit of the amplifier.

In lieu of NPN transistor 10, a PNP transistor can be used if the polarity of bias supply 12 is reversed and if the polarity and direction of the AGC signal are reversed. Under the latter conditions, the polarity of the diode 32 would be reversed. Also a vacuum tube may be used in lieu of transistor 10.

sistor 10 by capacitor 20. An AGC to the base of transistor 10 by way Operation of circuit The operation of the circuit of FIG. 1 will be explained reference to the gain characteristic thereof shown in FIG. 2, which is divided into two sections, I and II, for purposes of explanation.

In section I the strength of the incoming signal is assumed sufficient to overcome the inherent threshold of the AGC circuit (not indicated) as as to generate a moderate AGC voltage will increase the bias at the thereby move the operating point of transistor 10 from its normal point (maximum gain) to a point nearer saturation at which less gain will be provided. Because the AGC voltage increases the forward bias of transistor 10 as the amplitude of the input signal increases, it is referred to as forward AGC. (In a conventional or reverse AGC circuit, the AGC voltage moves the operating point toward the cutoff point of the transistor as the signal base of transistor 10 and Istrength increases.) The use of forward AGC in lieu of reverse AGC reduces harmonic and cross modulation distortion, since with forward AGC, the direct current supplied to the transistor is greater, allowing it to handle larger A.C. signals. Also, when forward AGC is used, the peaks of the incoming signal will drive the transistor deeper into saturation, where relatively gradual limiting rather than sharp clipping occurs.

When the amplifier is operating along section I of its gain characteristic, the AGC voltage will become more positive as the signal strength increases and will thereby reduce the gain of the stage at the rate indicated by the slope of the solid line labeled R28+R30. The slope of this spass? on lead 26. An increase in the AGC voltage line is governed by the value of emitter resistors 28 and 30, which constitute the effective DC impedance connecting the emitter of transistor 10 to ground. These resistors act to produce a relatively large amount of degeneration on the AGC voltage and thereby render the gain control sensitivity of the stage low. Diode 32 will play no part when the circuit is operating in section I since the voltage drop across resistor 30 will not be sufficient to overcome the forward offset voltage of diode 32.

When the input signal strength increases sufficiently so that the drop across resistor 30 will forward bias diode 32, operation in section II (the solid line designated R28) will occur. In section 1I diode 32 will have a far lower impedance than resistor 30 so that resistor 28 will effectively constitute almost the entire impedance connecting the emitter of transistor 10 to ground. The AGC voltage will consequently be degenerated less and hence will be more effective in reducing the gain of the circuitas indicated by the steeper slope of the gain characteristic in section II. In absence of diode 32 the slope of the gain characteristic would be similar to that in region I, as indicated by the broken line also labeled R28+R30.

It will thus be apparent that in the presence of strong incoming signals (section II) the gain control sensitivity of the amplifier will be high, thereby reducing AGC current requirements and providing a more constant output as signal strength varies. In the presence of weaker incoming signals (section I) the gain control sensitivity will be reduced and the gain of the RF stage will be high, thereby reducing noise content in the output of the receiver.

While there has been described what is at present considered to be the preferred embodiment of the invention it will be apparent that various modifications and other embodiments thereof will occur to those skilled in the -art within the scope of the invention. Accordingly, it is desired that the scope of the invention be limited by the appended claims only.

I claim:

1. A gain controllable amplifier comprising:

(a) an electronic valve having input, common, and output electrodes,

(b) a direct current bias source having first and second terminals,

(c) means connecting said output electrode of said valve to said first terminal of said source, said means including an output terminal for said amplifier,

(d) means for supplying an input signal between one of said terminals of said source and said input electrode of said valve,

(e) means for varying the direct current potential of said input electrode of said valve in relation to the potential of said one terminal of said source, and

(f) voltage controlled variable impedance means, connected between said common electrode of said valve and said second terminal of said source, for causing the gain of said amplifier to decrease at a slower rate when said direct current potential of said input electrode of said valve is varied from a given value to a greater value than when said direct current potential is varied from said greater value to a still greater value. l

2. The combination of claim 1 wherein said impedance means has a current versus voltage characteristic such that the current therethrough increases at a slower rate when the voltage thereacross is varied from a given value to a greater value than when said voltage varies from said greater value to a still greater value.

3. The combination of claim 2 further comprising a capacitor connected in parallel with said impedance means.

4. The combination of claim 2 wherein said impedance means comprises two serially-connected resistors and a diode, said diode being connected in parallel with one of said resistors, said diode having a forward offset potential and being poled to conduct direct current from said source in the forward direction.

5. The combination of claim 4 further comprising a capacitor connected in parallel with said two serially-conranged to vary the potential difference between said base nected resistors. ele tr d and the other terminal of said source so as to 6. The combination of claim 1 wherein said (e) means increase the forward bias of said transistor in proportion comprises a forward automatic gain control circuit arto the magnitude of the signal across said load impedance. ranged to vary the potential of said input electrode of said 5 10. The amplilier of claim 7 wherein said two resistors valve in proportion to the amplitude of the output signal are capacitively bypassed. y of said amplifier. 11. The ampliiier of claim 7 wherein said load imped- 7. A controllable gain amplifier, comprising: ance comprises a transformer, the primary winding thereof t (a) a source of direct current bias potential; being connected in circuit between said collector electrode (b) a transistor having base, emitter, and collector elecl0 and said one terminal of said source, said (e) means comtrodes, prises a forward automatic gain control circuit arranged to (c) a load impedance connecting the collector electrode vary the potential between said base and said other termiof said transistor to one terminal of said source, nal of said source so as to increase the forward bias of (d) means for supplying an input signal between said said transistor in proportion to the magnitude of the sigbase electrode and the other terminal of said source, 15 nal across said load impedance, said device of clause (f) (e) means for varying the direct current bias potential is a diode having a forward offset potential and poled to of said base terminal, and conduct current from said source in the forward direc- (f) a pair of resistors serially connected between said tion, and wherein said two resistors are capacitively byemitter and said other terminal of said source, one passed. of said resistors being paralleled by a device which 20 References Cited has (l) a relatively high resistance when less than a UNITED STATES PATENTS predetermined potential is applied thereacross and (2) a relatively low resistance when greater than said 8971353 7/1959 Schwelss r- 250`20 d termi ed otential is a lied thereacross 3014186 12/1961 Webster 330`24 pre e n p pp t 3 234 469 2/1966 Gunn 325 319 X `8. The .amplifier of claim 7 wherein sald device 1s a n 313096 17 3/1967 Lancaster et al 330`29 X current in the forward direction from said source.

9. The amplifier of claim 7 wherein said (e) means ROY LAKE Pnmary Exammer comprises a forward automatic gain control circuit ar- J. B. MULLINS, Assistant Examiner. 

